CN110274961A - The non-linear acoustic emission system recognition methods of pipeline microdefect is detected based on PEC - Google Patents
The non-linear acoustic emission system recognition methods of pipeline microdefect is detected based on PEC Download PDFInfo
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Abstract
The invention discloses a kind of non-linear acoustic emission system recognition methods of pipeline microdefect based on PEC detection, workpiece is tested using PEC pumping signal, output signal is obtained using sensor, establishes the relationship between fault in material physical property and frequency-domain index, is analyzed for frequency domain character;Flat-die type is slided using with externally input nonlinear auto-companding, establishes the Model in Time Domain between input signal and output response;PEC is detected and is combined with MARMAX model, the frequency response function of NARMAX model is extracted from time domain data;The quantitative relationship between excitation input and system response is established, to obtain the index of evaluation structure health status.Using linear time model and frequency domain character extraction and analysis, the PEC data analysis of structure health assessment is had studied.
Description
Technical field
The invention belongs to ultrasonic non-destructive inspection techniques field more particularly to a kind of pipeline microdefects based on PEC detection
Non-linear acoustic emission system recognition methods.
Background technique
Production equipment is continued to develop with the development of modern industrial technology, gradually forms scale, automation, high efficiency
The characteristics of.The fault diagnosis and non-destructive testing technology of engineering system have many requirements, and these requirements can effectively assess engineering system
Working condition, effectively prevent system Premature Distress and catastrophic failure occur a possibility that.Impulse eddy current (PEC) test
It is a kind of structure non-destructive testing technology of fast development, if metal thickness measures, multilayer material defects detection and Corrosion monitoring.It is logical
The influence and response understood in time domain and frequency domain is crossed, theory of representation and Feature Extraction Technology based on PEC are developed.
Traditional nondestructive detecting technology of vortex analyzes structure output response using only interpretation technology, significant by extracting
Information characteristics, such as flaw size, the quantitatively characterizing of position and classification comes evaluation structure health and integrality.This interpretation skill
Art needs that there is the reference differential of zero defect condition to detect for structural health.However, reference signal is easy by industry
The influence of other unstable environmental conditions in, and differential signal cannot disclose the built-in system machine generated by fault of construction
System.It is difficult to find corresponding interpretation technology extraction internal information to determine influence of the defect to structural system condition.
There are many applications, including system identification in engineering system fault diagnosis based on the method for model.Defect is considered as
The Unknown worm of model parameter or interference are used as the feature for indicating component defect.But this method needs engineering system
Detailed physical model, this is infeasible in practice.For the difficult point for overcoming physical model, the invention proposes a kind of new bases
In the method for model.
Summary of the invention
The technical problem to be solved by the invention is to provide a kind of non-linear sound of pipeline microdefect based on PEC detection
Emission system recognition methods has studied the PEC number of structure health assessment using linear time model and frequency domain character extraction and analysis
According to analysis.
The technical solution adopted by the present invention to solve the technical problems is: it is microcosmic to provide a kind of pipeline based on PEC detection
The non-linear acoustic emission system recognition methods of defect, this approach includes the following steps, step 1, is swashed using PEC (Pulsed eddy current testing)
Encourage signal to test workpiece, obtain output signal using sensor, establish fault in material physical property and frequency-domain index it
Between relationship, for frequency domain character analyze;Typical PEC experimental system is built before step 1, uses carrier frequency and bandwidth
Suitable miniature angle beam sensor, function generator, oscillograph, transmitting and receiver etc..
Step 2, flat (NARMAX) model is slided using with externally input nonlinear auto-companding, establishes input stimulus letter
Model in Time Domain number between output response.
Step 3, PEC is detected and is combined with MARMAX model, the frequency that NARMAX model is extracted from time domain data is rung
Answer function (FRF).
Step 4, the quantitative relationship between excitation input and system response is established, to obtain the finger of evaluation structure health status
Mark.
According to the above technical scheme, in the step 2, NARMAX modelling technique is to indicate input signal and structural system
The Model in Time Domain of dynamic behaviour relationship between output response.NARMAX model is established, from the identified non-of examined system
Frequency response function, the representative frequency domain character of extraction system from frequency response function, according to frequency are determined in linear model
The variation of receptance function carries out system fault diagnosis and structure non-destructive testing.
According to the above technical scheme, frequency response function is determined from the identified nonlinear model of examined system,
Black-box modeling specially is established using discrete input and output time domain data, is included the following steps, step 1, proposes to have external defeated
The nonlinear auto-companding entered slides flat NARMAX model structure, provides and closes about SISO nonlinear dynamic system input-output
The unified representation of system is modeled as follows by nonlinear difference equation:
Y (t)=f (y (t-1) ..., y (t-ny),u(t-1),...,u(t-nu),ε(t-1),...,ε(t-nε))+ε(t)
(1)
Wherein, y (t) is output error, and u (t) is error originated from input, ε (t) noise sequence;ny、nu、nεIt is the x moment respectively, is
The time delay step number of system output, input and noise item;F () be nonlinear mapping function, it be it is unknown, need from defeated
Enter-output data in identify, true functionNonlinear approximation f be by with finite dimension parameter vector θ parameterized function race come
It realizes:
Noise item ε (t) can not be measured directly, can only be substituted, be defined as follows using prediction error:
Wherein, y (t) is the reality output measured,For the output of prediction.
Equation (1) can be rewritten as follows by mapping finite dimensional vector:
Here, θ is to have model parameter to be estimated,For regression vector, x (t) is lag output error, input mistake
Difference and noise sequence,
X (t)=[y (t-1) ... y (t-ny)u(t-1)…u(t-nu)ε(t-1)…ε(t-nε)]T (5)
Step 2, the input-output data of given system can be modeled by linear system and efficiently perform measuring system
FRF, frequency response H (ejω) it can be construed to the transmission function of assessment, is defined as:
Wherein, ω is input frequency, and b (k) is individual system output data, and a (l) is individual system input data.
According to the above technical scheme, frequency response function acts in the step 3: fault in material is expressed as Unknown worm or right
The variable of the interference of the Model in Time Domain parameter of structure dynamics behavior, model parameter can be able in frequency response function (FRF)
Instruction.
According to the above technical scheme, in the step 4, with known FRF model comparision after acquisition FRF, become in system parameter
It is assessed when change, under the frame of NARMAX modeling and the frequency analysis based on FRF, by analyzing the system indicated by system FRF
Identify that the frequency domain character of nonlinear model carries out the fault diagnosis of engineering system.
The beneficial effect comprise that: linear time model and frequency domain character extraction and analysis are utilized, structure is had studied
The PEC data of health evaluating are analyzed, and the invention proposes one kind to output and input structural system model between response based on excitation
Different perspectives monitoring structural health conditions new method.
Detailed description of the invention
Present invention will be further explained below with reference to the attached drawings and examples, in attached drawing:
Fig. 1 is the embodiment of the present invention based on the PEC non-linear acoustic emission system identification technology of pipeline microdefect detected
Flow diagram;
Fig. 2 is the non-linear acoustic emission system identification technology of pipeline microdefect that the embodiment of the present invention is detected based on PEC
Design of experiment.
Specific embodiment
In order to make the objectives, technical solutions, and advantages of the present invention clearer, with reference to the accompanying drawings and embodiments, right
The present invention is further elaborated.It should be appreciated that described herein, specific examples are only used to explain the present invention, not
For limiting the present invention.
As shown in Figure 1, the embodiment of the present invention identifies skill based on the non-linear acoustic emission system of pipeline microdefect that PEC is detected
PEC signal is analyzed in comprising the steps of: using linear time modeling and linear frequency analysis for art;Characteristic parameter is extracted, is used
In the different crack of identification;The pumping signal of PEC and output response are input to linear time model, which is based on NARMAX
Model foundation.By being tested to experimental data compared with existing method, and by with existing greatest gradient method
Comparison, demonstrate the efficiency and applicability of the method for the present invention.Determine frequency response function specifically: defeated using discrete input
Time domain data establishes black-box modeling out.Frequency response function (FRF) is analyzed for analyzing Model in Time Domain and extracting feature to diagnose
The fault state of engineering system.The system failure is reflected in the variation of Model in Time Domain, this shows in the variation of system FRF.Cause
This, the variation of system FRF can be used for carrying out system fault diagnosis structure NDT.
As shown in Fig. 2, a kind of non-linear acoustic emission system of pipeline microdefect based on PEC detection of the invention identifies skill
Art, experiment porch are built as follows: establishing typical TOFD experimental system, experiment has used miniature angle beam sensor (MSW-
QC type, Benchmark series) and model W-211 (45 °) voussoir, the carrier frequency and bandwidth of sensor be respectively
2.25MHz and 1.5MHz, the angle of wedge are 45 °.Use common bloom as sample, sample with a thickness of 2.25cm, face crack
Depth is 1.25cm.Two sensors are placed, middle position of the crack on bloom between transmitter and receiver is made, this
Ensure that ultrasonic signal is traveling to most short flight time when crack reaches receiver then from transmitter.
AFG320 function generator and TDS3000 series oscillograph are used in experiment, function generator is connected to transmitting
Device, ultrasonic signal is sent sample by transmitter, and is sent to oscillograph, and oscillograph collects the reflectance ultrasound from receiver
Wave signal.Experiment ultrasonic signal for Crack Detection is obtained by the A sweep that sample frequency is 100MHz.When transmitter and connect
When receiving device wide apart, in the diffracting ultrasonic signals insertion noise from crack tip.
Method based on linear time model and frequency-domain analysis, establishes between fault in material physical property and frequency-domain index
Relationship the mathematical model of structural system kinetics mechanism, material are determined according to inputoutput data using NARMAX modelling technique
Material defect shows as the interference of Unknown worm or the Model in Time Domain parameter to structure dynamics behavior, and the defect of this variable indicates energy
Enough displays in frequency response function (FRF).The variable of structural system physical characteristic can reflect in Model in Time Domain, this can also
It is indicated with variation by system FRF.
It should be understood that for those of ordinary skills, it can be modified or changed according to the above description,
And all these modifications and variations should all belong to the protection domain of appended claims of the present invention.
Claims (5)
1. a kind of non-linear acoustic emission system recognition methods of pipeline microdefect based on PEC detection, which is characterized in that this method
Include the following steps, step 1, workpiece is tested using PEC pumping signal, obtains output signal using sensor, establish
Relationship between fault in material physical property and frequency-domain index is analyzed for frequency domain character;
Step 2, flat-die type is slided using with externally input nonlinear auto-companding, establishes input signal and output response
Between Model in Time Domain;
Step 3, PEC is detected and is combined with MARMAX model, the frequency response letter of NARMAX model is extracted from time domain data
Number;
Step 4, the quantitative relationship between excitation input and system response is established, to obtain the index of evaluation structure health status.
2. the pipeline microdefect non-linear acoustic emission system recognition methods according to claim 1 based on PEC detection,
It is characterized in that, in the step 2, establishes NARMAX model, determined from the identified nonlinear model of examined system
Frequency response function, the representative frequency domain character of extraction system from frequency response function, according to the variation of frequency response function
To carry out system fault diagnosis and structure non-destructive testing.
3. the pipeline microdefect non-linear acoustic emission system recognition methods according to claim 2 based on PEC detection,
It is characterized in that, frequency response function is determined from the identified nonlinear model of examined system, specially using discrete
Input and output time domain data establishes black-box modeling, includes the following steps,
Step 1 proposes that there is externally input nonlinear auto-companding to slide flat NARMAX model structure, provides about SISO
The unified representation of nonlinear dynamic system Input output Relationship is modeled as follows by nonlinear difference equation:
Y (t)=f (y (t-1) ..., y (t-ny),u(t-1),...,u(t-nu),ε(t-1),...,ε(t-nε))+ε(t)
(1)
Wherein, y (t) is output error, and u (t) is error originated from input, ε (t) noise sequence;ny、nu、nεRespectively be output, input and
The time delay step number of noise;F () be nonlinear mapping function, it be it is unknown, need to know from input-output data
Not, true functionNonlinear approximation f be by being realized with finite dimension parameter vector θ parameterized function race:
Noise item ε (t) is defined as follows:
Wherein, y (t) is the reality output measured,For the output of prediction.
Equation (1) can be rewritten as follows by mapping finite dimensional vector:
Here, θ is to have model parameter to be estimated,For regression vector, x (t) be lag output error, error originated from input and
Noise sequence,
X (t)=[y (t-1) ... y (t-ny)u(t-1)…u(t-nu)ε(t-1)…ε(t-nε)]T (5)
Step 2, the input-output data of given system can be modeled by linear system and efficiently perform measuring system FRF,
Frequency response can be construed to the transmission function of assessment, is defined as:
Wherein, ω is input frequency, and b (k) is individual system output data, and a (l) is individual system input data.
4. the pipeline microdefect non-linear acoustic emission system identification side according to claim 1 or 2 based on PEC detection
Method, which is characterized in that frequency response function acts in the step 3: fault in material is expressed as Unknown worm or to structure dynamics
The variable of the interference of the Model in Time Domain parameter of behavior, model parameter can be indicated in frequency response function.
5. the pipeline microdefect non-linear acoustic emission system identification side according to claim 1 or 2 based on PEC detection
Method, which is characterized in that in the step 4, with known FRF model comparision after acquisition FRF, assessed in system parameter variations,
Under the frame of NARMAX modeling and the frequency analysis based on FRF, by analyze identified by the system that system FRF is indicated it is non-thread
Property model frequency domain character carry out engineering system fault diagnosis.
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